Effect of C on Vacancy Migration in α-Iron

Chu Chun Fu; Estelle Meslin; Alain Barbu; F. Willaime; V. Oison

doi:10.4028/www.scientific.net/SSP.139.157

Paper Titles

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Ab-Initio Calculation for the Study of Nano Scale Silicon Based Device Structure
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Modelling of Elastic Modulus and Molecular Structure Interrelationship of an Oriented Crystalline Polymer
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Reaction Rate as an Effective Tool for Analysis of Chemical Diffusion in Solids
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Simulation of the Columnar-to-Equiaxed Transition in Alloy Solidification - The Effect of Nucleation Undercooling, Density of Nuclei in Bulk Liquid and Alloy Solidification Range on the Transition
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Simulation of Surface-Enhanced Ordering in Smectic Films
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Atomic Scale Modelling of Materials: A Prerequisite for any Multi-Scale Approach to Structural and Dynamical Properties
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Morphological Evolution of Intragranular Void under the Thermal-Stress Gradient Generated by the Steady State Heat Flow in Encapsulated Metallic Films: Special Reference to Flip Chip Solder Joints
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Effect of C on Vacancy Migration in α-Iron
p.157

HomeSolid State PhenomenaSolid State Phenomena Vol. 139Effect of C on Vacancy Migration in α-Iron

Effect of C on Vacancy Migration in α-Iron

Abstract:

Carbon atoms are always present in Fe-based materials, either as impurities even in high purity samples or as an intrinsic constituent in steels. Density Functional Theory calculations have been performed to study the interaction between C atoms and vacancies (V) in α-Fe. We find that the formation of VCn complexes is energetically favourable for n ≤ 3, with VC2 being the most stable one. The energy gain corresponding to the clustering reaction VCn-1 + C → VCn depends mainly on the strength of C-C covalent bonds. The vacancy diffusivity is shown to be significantly modified by the formation of vacancy-carbon complexes, exhibiting non-Arrhenius behaviour. Effective vacancy diffusion coefficients in α-Fe are calculated as a function of temperature and carbon content using a simplified thermodynamic model. The results are discussed in detail in the limiting case of excess of C with respect to vacancies.